Polyamine derivatives as selective RNaseA mimics.

Site-selective scission of ribonucleic acids (RNAs) has attracted considerable interest, since RNA is an intermediate in gene expression and the genetic material of many pathogenic viruses. Polyamine-imidazole conjugates for site-selective RNA scission, without free imidazole, were synthesized and tested on yeast phenylalanine transfer RNA. These molecules catalyze RNA hydrolysis non-randomly. Within the polyamine chain, the location of the imidazole residue, the numbers of nitrogen atoms and their relative distances have notable influence on cleavage selectivity. A norspermine derivative reduces the cleavage sites to a unique location, in the anticodon loop of the tRNA, in the absence of complementary sequence. Experimental results are consistent with a cooperative participation of an ammonium group of the polyamine moiety, in addition to it's binding to the negatively charged ribose-phosphate backbone, as proton source, and the imidazole moiety as a base. There is correlation between the location of the magnesium binding sites and the RNA cleavage sites, suggesting that the protonated nitrogens of the polycationic chain compete with some of the magnesium ions for RNA binding. Therefore, the cleavage pattern is specific of the RNA structure. These compounds cleave at physiological pH, representing novel reactive groups for antisense oligonucleotide derivatives or to enhance ribozyme activity.

Structural analysis of metal ion ligation to nucleotides and nucleic acids using pulsed EPR spectroscopy.

Metal ions play key structural and functional roles in many nucleic acid systems, particularly as required cofactors for many catalytic RNA molecules (ribozymes). We apply the pulsed EPR technologies of electron spin-echo envelope modulation and electron spin-echo-electron nuclear double resonance to the structural analysis of the paramagnetic metal ion Mn(II) bound to nucleotides and nucleic acids. We demonstrate that pulsed EPR, supplemented with specific isotope labeling, can characterize ligation to nucleotide base nitrogens, outer-sphere interactions with phosphate groups, distances to sites of specific (2)H atom labels, and the hydration level of the metal ion. These techniques allow a comprehensive structural analysis of the mononucleotide model system MnGMP. Spectra of phenylalanine-specific transfer RNA from budding yeast and of the hammerhead ribozyme demonstrate the applicability of the methods to larger, structured RNA systems. This suite of experiments opens the way to detailed structural characterization of specifically bound metal ions in a variety of ribozymes and other nucleic acids of biological interest.

Ribonuclease P catalysis requires Mg2+ coordinated to the pro-RP oxygen of the scissile bond.

Ribonuclease P (RNase P) is an essential enzyme whose action produces the mature 5' termini of all cellular and organellar transfer RNA molecules. In bacteria, the catalytic subunit of RNase P is an RNA molecule which by itself can bind substrate pre-tRNA, select and hydrolyze the correct phosphodiester bond, and release product tRNA. The simple requirements of the reaction-a monovalent cation such as K+ or NH4+ and the divalent cation Mg2+ (or Mn2+)-have prompted proposals that all aspects of phosphodiester bond hydrolysis might be accomplished by one or more divalent metal cations coordinated to the enzyme or substrate. To precisely localize the ligands of catalytically-involved Mg2+, we assayed cleavage by Escherichia coli RNase P RNA of pre-tRNA in which specific pro-Rp phosphate oxygens were replaced with sulfur. RNase P cleavage was targeted to that bond, at or nearest to the normal cleavage site, at which Mg2+ or Mn2+ could be coordinated. Single-turnover kinetics demonstrated that the apparent rate constant for the hydrolysis event was determined quantitatively by the affinity of the divalent cation (Mg2+ or Mn2+) for the atom (O or S) at the pro-Rp position of the scissile phosphodiester bond. We propose a model for pre-tRNA cleavage in which an essential Mg2+ ion is coordinated directly to the pro-Rp phosphate oxygen and indirectly to two other ligands near the scissile bond: the upstream ribose 2'-hydroxyl and the downstream purine N7. This catalytic Mg2+ ion most likely positions and deprotonates a water molecule for in-line nucleophilic attack on the scissile bond phosphorus.

A single editing event is a prerequisite for efficient processing of potato mitochondrial phenylalanine tRNA.

In bean, potato, and Oenothera plants, the C encoded at position 4 (C4) in the mitochondrial tRNA Phe GAA gene is converted into a U in the mature tRNA. This nucleotide change corrects a mismatched C4-A69 base pair which appears when the gene sequence is folded into the cloverleaf structure. C-to-U conversions constitute the most common editing events occurring in plant mitochondrial mRNAs. While most of these conversions introduce changes in the amino acids specified by the mRNA and appear to be essential for the synthesis of functional proteins in plant mitochondria, the putative role of mitochondrial tRNA editing has not yet been defined. Since the edited form of the tRNA has the correct secondary and tertiary structures compared with the nonedited form, the two main processes which might be affected by a nucleotide conversion are aminoacylation and maturation. To test these possibilities, we determined the aminoacylation properties of unedited and edited potato mitochondrial tRNAPhe in vitro transcripts, as well as the processing efficiency of in vitro-synthesized potato mitochondrial tRNAPhe precursors. Reverse transcription-PCR amplification of natural precursors followed by cDNA sequencing was also used to investigate the influence of editing on processing. Our results show that C-to-U conversion at position 4 in the potato mitochondrial tRNA Phe GAA is not required for aminoacylation with phenylalanine but is likely to he essential for efficient processing of this tRNA.

The ribosomal environment of tRNA: crosslinks to rRNA from positions 8 and 20:1 in the central fold of tRNA located at the A, P, or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl) uridine ("acp3U") at position 20:1 of lupin tRNAMet was coupled to a photoreactive diazirine derivative. Similarly, the 4-thiouridine at position 8 of Escherichia coli tRNAPhe was modified with an aromatic azide. Each of the derivatized tRNAs was bound to E. coli ribosomes in the presence of suitable mRNA analogues, under conditions specific for the A, P, or E sites. After photoactivation of the diazirine or azide groups, the sites of crosslinking from the tRNAs to 16S or 23S rRNA were analyzed by our standard procedures, involving a combination of ribonuclease H digestion and primer extension analysis. The crosslinked ribosomal proteins were also identified. The results for the rRNA showed a well-defined series of crosslinks to both the 16S and 23S molecules, the most pronounced being (1) an entirely A-site-specific crosslink from tRNA position 20:1 to the loop-end region (nt 877-913) of helix 38 of the 23S RNA (a region that has not so far been associated at all with tRNA binding), and (2) a largely P-site-specific crosslink from tRNA position 8 to nt 2111-2112 of the 23S RNA (nt 2112 being a position that has previously been identified in footprinting studies as belonging to the ribosomal E site). The data are compared with results from a parallel study of crosslinks from position 47 (also in the central fold of the tRNA), as well as with previously published crosslinks from the anticodon loop (positions 32, 34, and 37) and the CCA-end region (position 76, and the aminoacyl residue).

Unfolding of the tertiary structure of specific tRNA and ribosomal 5S RNA from plants as studied with hydroxyl radicals.

Ribosomal 5S RNA is present in all eubacterial and eukaryotic ribosomes. Despite a large amount of experimental data on the primary and secondary structures of these types of molecules, details of their tertiary structure and their precise function in protein biosynthesis are still not known. Recently we have proposed a new model for the tertiary structure of plant 5S rRNA. In this study we applied the Fe(II)-mediated cleavage reaction to test the model. The data presented here provide experimental evidence that in the 5S rRNA molecule only a few nucleotides are buried in the tertiary structure. Similar experiments performed with methionine initiator tRNA gave results which imply the difference in its structure when compared with the X-ray structure of yeast tRNAPhe.

Variations during leaf development of the relative amounts of two bean (Phaseolus vulgaris) chloroplast tRNAs(Phe) which differ in their minor nucleotide content.

Bean (Phaseolus vulgaris cv. Saxa) chloroplasts contain two tRNA(Phe) species, namely tRNA(Phe)1 and tRNA(Phe)2. By sequence determination, we show that tRNA(Phe)2 is identical to the previously sequenced tRNA(Phe)1 except for two undermodified nucleotides. By reversed-phase chromatography analyses, we demonstrate that the relative amounts of these two chloroplast tRNAs(Phe) vary during leaf development: in etiolated leaves the undermodified tRNA(Phe)2 only represents 15% of total chloroplast tRNA(Phe), during development and greening it increases to reach 60% in 8-day-old leaves, and it then decreases to 9% in senescing leaves.

Specificity and mechanism of the cleavages induced in yeast tRNAPhe by magnesium ions.

The specificity of magnesium ion-induced hydrolysis of yeast tRNAPhe in solution was studied as a function of the excess of Mg(II) ions and pH. The major cuts at phosphates 16 and 20 as well as minor cleavages at phosphates 17, 18, 21, 34 and 36 occur at all pH values in the range of 8.0-9.5, and at a molar excess of magnesium ions over the tRNA ranging from 125 to 5000. In yeast tRNA(Phe)-Y the efficiency of the anticodon and D-loop cleavages is considerably decreased while the differently modified Y-base of yellow lupin tRNA(Phe) lowers the specificity of the weak anticodon loop cleavages. The mechanism of the Mg(II)-induced cleavages is discussed on the basis of yeast tRNA(Phe) crystal structure data, and the two major D-loop cleavages are thought to be effected from two distinct magnesium binding sites. The possibility of probing the environments of magnesium binding sites in tRNAs by the induced cleavages is demonstrated, and the relevance of magnesium-induced tRNA cleavages to RNA catalysis is discussed.